RELATED APPLICATION

This application claims the priority benefit of U.S. Provisional Application Ser. No. 60/973,143 filed Sep. 17, 2007.

TECHNICAL FIELD

Embodiments of the inventive subject matter generally relate to the field of integrated circuits, and, more particularly, to voltage-controlled oscillators.

BACKGROUND

A voltage-controlled oscillator (VCO) is an electronic circuit that produces an oscillating signal with a frequency that is related to a control voltage applied at the input of the VCO. VCOs typically include an inductance/capacitance (LC) tank circuit having at least one variable capacitor, or varactor. Varactors are voltage-tunable capacitors having a capacitance that varies as a function of the DC voltage across the varactor. The one or more varactors in the LC tank circuit typically help adjust the frequency of oscillation of the VCO in response to varying levels of the control voltage. VCOs are used within phase-locked loops (PLLs) for various applications, such as wired and wireless communications.

SUMMARY

Various embodiments are disclosed of a method and apparatus for determining control voltage limits associated with a control voltage received by a VCO and controlling a capacitance associated with the VCO based on the control voltage to tune the frequency of oscillation of the VCO. According to one embodiment, a VCO comprises a first circuit, a second circuit, a comparator circuit, and a control unit. The first circuit is operable to determine an output common mode voltage associated with an output of the VCO. The second circuit is operable to generate an upper control voltage limit and a lower control voltage limit associated with a control voltage received by the VCO based, at least in part, on the output common mode voltage. The comparator circuit is operable to compare the control voltage to the upper and lower control voltage limits. The control unit is operable to determine whether to change a switched capacitance associated with the VCO based, at least in part, on whether the control voltage is outside the upper and lower control voltage limits.

BRIEF DESCRIPTION OF THE DRAWINGS

The present embodiments may be better understood, and numerous objects, features, and advantages made apparent to those skilled in the art by referencing the accompanying drawings.

FIG. 1 is a block diagram of one embodiment of a PLL;

FIG. 2A is a circuit diagram of one embodiment of a VCO with control range limiter circuitry;

FIG. 2B is a diagram of one example of a C-V curve associated with varactors of the VCO;

FIG. 3 is a flow diagram of one example of a method for determining control voltage limits associated with a VCO and tuning the frequency of oscillation of the VCO;

FIG. 4 is a flow diagram of one example of a method for comparing a control voltage received by the VCO to the control voltage limits to determine whether to change the capacitance associated with the VCO; and

FIG. 5 is a block diagram of one embodiment of a communication system.

DESCRIPTION OF EMBODIMENT(S)

The description that follows includes exemplary circuits, systems, and methods that embody techniques of the present inventive subject matter. However, it is understood that the described embodiments may be practiced without these specific details. For instance, although examples refer to using an amplifier circuit to determine upper and lower control voltage limits associated with a control voltage based on an output common mode voltage of a voltage-controlled oscillator, in some embodiments, other circuitry can be used to determine the upper and lower control voltage limits based on the output common mode voltage. In other instances, well-known structures and techniques have not been shown in detail in order not to obfuscate the description.

FIG. 1 is a block diagram of one embodiment of a phase-locked loop (PLL) 100. As illustrated, the PLL 100 includes a phase frequency detector 105, a charge pump 110, a loop filter 115, a voltage-controlled oscillator (VCO) 120, and a divider 125. The PLL 100 synchronizes an output signal (OUT) generated by the VCO 120 at the output terminal of the PLL with a reference signal (REF) received at one of the input terminals of the PLL with respect to frequency and phase. The output signal of the PLL 100 is first processed within the feedback loop of the PLL to generate a feedback signal (FB). The PLL 100 can then compare the frequency and phase difference between the reference signal and the feedback signal to determine whether to adjust the output signal of the PLL 100 to achieve or maintain a specific phase and frequency relationship between the output signal and the reference signal, i.e., a locked state. In one example, if the feedback loop of the PLL 100 includes divide-by-N circuitry, the frequency of the output signal can be an integer multiple of the reference signal. In another example, if the PLL 100 is configured as a fractional-N PLL, the frequency of the output signal can be a non-integer (or fractional) multiple of the reference signal.

During operation, the phase frequency detector 105 compares the phase and frequency of the feedback signal to that of a reference signal. Based on the results of the comparison, the phase frequency detector 105 provides one or more control signals to the charge pump 100. The charge pump 100 generates a control voltage V_C for the VCO 120 based on the one or more control signal from the phase frequency detector 105 and provides the control voltage V_C to the VCO 120. The loop filter 115 (e.g., a low-pass filter) filters the control voltage V_C before it is provided to the VCO 120. The control voltage V_C controls the frequency of oscillation of the output signal of the VCO 120. The divider 125 in the feedback of the PLL 100 determines whether the output signal of the PLL is an integer multiple or a non-integer multiple of the reference signal.

The VCO 120 receives the control voltage V_C and adjusts (or maintains) the frequency of oscillation of the output signal based on the control voltage V_C. The VCO 120 comprises control range limiter circuitry 122 for determining upper and lower control voltage limits associated with the control voltage V_C and for controlling a capacitance associated with the VCO based on the control voltage V_C to tune the frequency of oscillation of the VCO, as will be further described below with reference to FIGS. 2A-5.

It should be noted that the components described with reference to FIG. 1 are meant to be exemplary only, and are not intended to limit the invention to any specific set of components or configurations. For example, in various embodiments, one or more of the components described may be omitted, combined, modified, or additional components included, as desired. For instance, in some embodiments, the feedback path of the PLL 100 may not include a divider 125 and/or may include additional circuitry besides the divider 125.

FIG. 2A is a circuit diagram of one embodiment of a VCO 120 with control range limiter circuitry. As illustrated, VCO 120 comprises an LC tank circuit, a pair of cross-coupled PMOS transistors 215 and 216, a pair of cross-coupled NMOS transistors 217 and 218, an amplifier circuit, a comparator circuit, and a control unit 240. The LC tank circuit includes a center-tapped inductor 202, varactors 204A and 204B (hereinafter “varactors 204”), switched capacitors 206A-N and 208A-N (hereinafter “capacitors 206” and “capacitors 208”), and switches 210A-N and 212A-N (hereinafter “switches 210” and “switches 212”). It is noted that in various embodiments the varactors 204 are configured as MOS varactors (MOSvars). The amplifier circuit includes amplifier 220, resistor R₁, and resistor R₂. The comparator circuit includes comparators 230A-B (hereinafter “comparators 230”). The input terminal of the VCO 120 receives a control voltage V_C (e.g., from a loop filter in a PLL, such as loop filter 115 shown in FIG. 1). The control voltage V_C is provided to the varactors 204 for controlling the frequency of oscillation of the VCO 120, and to the comparators 230 for determining whether the control voltage V_C is within a calculated range of control voltages, as will be further described below. The VCO 120 generates an oscillating output from the differential output signals V_OP and V_ON, which is provided to the output terminal of the VCO and, in PLL implementations (e.g., PLL 100 shown in FIG. 1), is also provided to the feedback path of the PLL.

The LC tank circuit determines the oscillating frequency of the VCO 120 and the transistors provide gain to amplify the oscillating signal. Within the LC tank circuit, the varactors 104 fine tune the frequency of oscillation of the VCO 120. For each varactor 104, the varactor capacitance is a function of the DC voltage across the varactor, which, in this case, is the differential voltage equal to the control voltage V_C minus the output common mode voltage V_OCM associated with the VCO 120. As illustrated in FIG. 2B, the behavior of the varactors 104, with respect to capacitance versus differential voltage (C-V), is nonlinear. At high and low differential voltage values, the varactor capacitance saturates at some minimum and maximum values, respectively. However, there is an in between range of voltage values where the capacitance change with respect to differential voltage is relatively constant and therefore approximately linear. In one implementation, “constant” may be defined to mean within 10% of the nominal value. In another implementation, “constant” may be defined to mean within 15% of the nominal value. It is noted, however, that in other implementations, “constant” can be defined more narrowly, e.g., within 5% of the nominal value, or more broadly, e.g., within 20% of the nominal value. The region of the C-V curve that meets this specification is considered the linear region associated with the varactors 104.

In various embodiments, the VCO control range limiter circuitry determine upper and lower control voltage limits associated with the control voltage V_C based on the measured output common mode voltage V_OCM associated with the VCO 120 to bias the control voltage V_C to the linear region of the C-V curve. Since the upper and lower control voltage limits are determined based on the measured output common mode voltage V_OCM, even if the output common mode voltage V_OCM changes, e.g., due to process variations, the upper and lower control voltage limits can change accordingly. In other words, the upper and lower control voltage limits can track the output common mode voltage V_OCM such that the control voltage V_C remains in the linear region of the C-V curve. This can ensure that the VCO gain (proportional to the derivative or slope of the C-V curve) remains “constant” over the control voltage range for a particular switched capacitance setting. In PLL implementations, a “constant” VCO gain can help maintain consistent PLL loop dynamics and stability over process variations.

When the control voltage V_C is within the range associated with the upper and lower control voltage limits, the control voltage V_C can be used to change the capacitance associated with the varactors 104 to fine tune the frequency of oscillation of the VCO 120. When the control voltage V_C is outside range associated with the upper and lower control voltage limits, the control unit 240 of the VCO 120 can switch on or off one or more pairs of capacitors 206 and 208 of the LC tank circuit to coarse tune the frequency of oscillation of the VCO such that the control voltage V_C falls within the linear region associated with the varactors 104. The LC tank circuit, the amplifier circuit, the comparator circuit, and the control unit of the VCO 120 are operable to determine the upper and lower control voltage limits associated with the control voltage V_C in order to operate within the linear region associated with the varactors 104, and are operable to tune the frequency of oscillation of the VCO 120 based on a received control voltage V_C (and the control voltage limits) to achieve a locked state, as will be described further below.

During operation, the LC tank circuit of VCO 120 determines the output common mode voltage V_OCM associated with the output of the VCO 120 using the center-tapped inductor 202. The LC tank circuit determines the output common mode voltage V_OCM based on the differential V_OP and V_ON output signals, i.e., the average value of the V_OP and V_ON signals. As illustrated, the output common mode voltage V_OCM is generated at the center-tap of the inductor 202. Measuring the output common mode voltage V_OCM as seen from the center tap of the inductor 202 positioned between the VCO outputs reduces the amount of noise that is introduced into the measurements. The output common mode voltage V_OCM is then provided to the amplifier 220 of the amplifier circuit. It is noted, however, that in other embodiments, the output common mode voltage V_OCM can be measured using other circuitry instead of the center-tapped inductor 202, such as an averaging circuit designed to average the differential V_OP and V_ON output signals without significantly loading the VCO 120.

The amplifier circuit determines an upper control voltage limit and a lower control voltage limit associated with the control voltage V_C received at the input of the VCO 120 based, at least in part, on the output common mode voltage V_OCM. As illustrated, in some examples, the amplifier circuit receives the output common mode voltage V_OCM at the noninverting input terminal of the amplifier 220. Current source 226 provides a constant current through resistors R₁ and R2. Since there is a constant current I_R through resistors R₁ and R₂, and I_R*R₁=V₁ and I_R*R₂=V₂, the amplifier circuit generates an output of V_OCM+I_RR₁ or V_OCM+V₁ at the output terminal of amplifier 220, and V_OCM−I_RR₂ or V_OCM−V₂ at node 225. The voltages V_OCM+V₁ and V_OCM−V₂ are provided to the comparator circuit to be used as the upper and lower control voltage limit, respectively. It is noted, however, that the upper and lower control voltage limits can be determined based on the output common mode voltage V_OCM using other types of circuits, e.g., circuits that are designed to add predetermined voltage values to the output common mode voltage V_OCM to generate the upper and lower control voltage limits. For instance, in other embodiments, current source 226 can provide a constant resistor-referenced current through the resistors, such that the values for V₁ and V₂ are constant. That is, the resistor-referenced current can be generated by applying a constant voltage (i.e., the bandgap voltage that ideally does not vary over process or temperature) over an on-chip resistor of the same type as R₁ and R₂, and thus V₁ is this constant voltage times the ratio of R₁ to the reference resistor.

The comparator 230A receives the upper control voltage limit and the control voltage V_C, and the comparator 230B receives the lower control voltage limit and the control voltage V_C. The comparator 230A compares the upper control voltage limit (e.g., V_OCM+V₁) to the control voltage V_C, and the comparator 230B compares the lower control voltage limit (e.g., V_OCM−V₂) to the control voltage V_C. If the control voltage V_C is greater than the upper control voltage limit, the comparator 230A generates a first control signal, and if the control voltage V_C is less than the lower control voltage limit, the comparator 230B generates a second control signal. In one example, if the control voltage V_C is greater than the upper control voltage limit, the comparator 230A enables the first control signal and the comparator 230B disables the second control signal, and if the control voltage V_C is less than the lower control voltage limit, the comparator 230B enables the second control signal and the comparator 230A disables the first control signal. Also, if the control voltage V_C is within the upper and lower control voltage limits, both control signals are disabled. The first and second control signals are then provided to the control unit 240. It is noted, however, that in other embodiments various types of comparator circuits can be used to determine whether the control voltage V_C is within the control voltage limits and to provide an indication to the control unit 240 of how the control voltage V_C compares to the control voltage limits.

The control unit 240 determines whether to change a switched capacitance associated with the LC tank circuit of the VCO 120 based, at least in part, on whether the control voltage V_C is outside the upper and lower control voltage limits. If the control unit 240 receives a first control signal (e.g., an enabled first control signal), which indicates that the control voltage V_C is greater than the upper control voltage limit, the control unit 240 switches on or switches off one or more pairs of the capacitors 206 and 208. For instance, in response to receiving a first control signal, when the VCO 120 includes a varactor whose capacitance decreases with control voltage V_C (e.g., NMOS varactor shown in FIG. 2A), the control unit 240 may switch off one or more pairs of the capacitors 206 and 208 (i.e., decrease the switched capacitance). In another implementation, when the VCO 120 includes a varactor whose capacitance increases with control voltage V_C (e.g., a PMOS varactor), the control unit 240 may switch on one or more pairs of the capacitors 206 and 208 (i.e., increase the switched capacitance). If the control unit 240 receives a second control signal (e.g., an enabled second control signal), which indicates that the control voltage V_C is less than the lower control voltage limit, the control unit 240 switches on or switches off one or more pairs of the capacitors 206 and 208. For instance, in response to receiving a second control signal, when the VCO 120 includes an NMOS varactor (e.g., FIG. 2A), the control unit 240 may switch on one or more pairs of the capacitors 206 and 208. In another implementation, when the VCO 120 includes a PMOS varactor, the control unit 240 may switch off one or more pairs of the capacitors 206 and 208.

In one example, the control unit 240 can switch on and off the capacitors 206 and 208 by sending control bits to the corresponding switches 210 and 212. It is noted that the control unit 240 can be implemented using hardware and/or software, such as digital circuitry or a state machine implemented on a processing unit, e.g., of a communication device.

In some examples, the range associated with the upper and lower control voltage limits can be relaxed at certain times during operation to build hysteresis into the circuit. For example, during locked operation, the range associated with the upper and lower control voltage limits can be relaxed (i.e., widened) to try to prevent a sudden change in switched capacitance while transmitting or receiving information in a communication system. With reference to the example shown in FIG. 2A, in one specific implementation, the range can be controlled by using programmable resistors R₁ and R₂ to change the value of V₁ and V₂, respectively.

As shown in FIG. 2A, the center-tapped inductor 202 is coupled in parallel to the varactors 104. In one example, where the varactors 104 are MOSvars, the varactors 104 are connected such that both the source and drain terminals of the varactor 204A and the source and drain terminals of the varactor 204B are connected to a control voltage V_C input terminal of the VCO 120, the gate terminal of the varactor 204A is connected to the V_OP output terminal, and the gate terminal of the varactor 204B is connected to the V_ON output terminal. The center-tapped inductor 202 and the varactors 204 can also be connected in parallel to the switched capacitors 206 and 208, to the cross-coupled PMOS transistors 215 and 216, and to the cross-coupled NMOS transistors 217 and 218. The cross-coupled PMOS transistors 215 and 216 are connected to supply V_DD, and the cross-coupled NMOS transistors 217 and 218 are connected to ground. In some examples, the transistors 215-218 are configured as field-effect transistors (FETs), e.g., MOSFETs.

Additionally, as shown in FIG. 2A, the center tap of the inductor 202 is connected to the non-inverting input terminal of the amplifier 220. The output terminal of the amplifier 220 is connected to a first terminal of resistor R₁ and to one of the input terminals of the comparator 230A. A second terminal of resistor R₁ is connected to the inverting input terminal of the amplifier 220 and to a first terminal of resistor R₂. A second terminal of resistor R₂ is connected to a first input terminal of comparator 230B and to current source 226, which is connected to ground.

Furthermore, the control voltage V_C input terminal is connected to the second input terminal of the comparator 230A and to the second input terminal of comparator 230B. The output terminals of comparators 230 are connected to input terminals of the control unit 240. The output terminal of the control unit 240 is connected to the switches 210 and 212, which are connected to the corresponding switched capacitors 206 and 208, respectively.

It should be noted that the components described with reference to FIG. 2A are meant to be exemplary only, and are not intended to limit the invention to any specific set of components or configurations. For example, in various embodiments, one or more of the components described may be omitted, combined, modified, or additional components included, as desired. For instance, in some embodiments, the switches 210 and 212 can be configured as transistors and/or the switched capacitor bank can include a single pair or multiple pairs of capacitors 106 and 108. Furthermore, in some embodiments, one or more of the components of the VCO 120, e.g., the control unit 240, can be implemented using hardware and/or software.

FIG. 3 is a flow diagram of one example of a method for determining control voltage limits associated with VCO 120 and tuning the frequency of oscillation of the VCO. At block 305, an output common mode voltage V_OCM associated with the output of the VCO 120 is determined. For example, the output common mode voltage V_OCM can be determined based on the differential V_OP and V_ON output signals. At block 310, an upper control voltage limit and a lower control voltage limit associated with the control voltage V_C is generated based, at least in part, on the output common mode voltage V_OCM. For example, a predetermined voltage value V₁ can be added to the common mode voltage V_OCM to generate the upper control voltage limit, and a predetermined voltage value V₂ can be subtracted from the common mode voltage V_OCM to generate the lower control voltage limit.

At block 315, the control voltage V_C is compared to the upper and lower control voltage limits. For example, the control voltage V_C is compared to V_OCM+V₁ and to V_OCM−V₂. At block 320, it is determined whether to change a switched capacitance associated with the VCO 120 based, at least in part, on whether the control voltage V_C is outside the upper and lower control voltage limits. As shown in the flow diagram of FIG. 4, in one example, if the control voltage V_C is greater than the upper control voltage limit (block 405), then the switched capacitance associated with the LC tank circuit of the VCO 120 is decreased (block 410), and if the control voltage V_C is less than the lower control voltage limit (block 415), then the switched capacitance associated with the LC tank circuit of the VCO 120 is increased (block 420). Also, if the control voltage V_C is within the range associated with the upper and lower control voltage limits, the current level of switched capacitance is maintained (block 425).

It should be understood that the depicted flow diagrams are examples meant to aid in understanding embodiments and should not be used to limit embodiments or limit scope of the claims. Embodiments may perform additional operations, fewer operations, operations in a different order, operations in parallel, and some operations differently. For instance, referring to FIG. 4, the comparison operations with respect to the upper and lower control voltage limits can be performed in parallel.

FIG. 5 is a block diagram of one embodiment of a communication system. As illustrated, the communication system may include a plurality of communication devices, such as personal computer (PC) 501, laptop 502, global positioning system (GPS) device 503, mobile phone 504, and server 505, transmitting and receiving information via a wireless and/or wired communication network 550. In various implementations, the communication devices comprise a transceiver having a VCO (e.g., VCO 120 of FIG. 2A) operable to implement at least some of the operations and features described above with reference to FIGS. 1-4, such as determining upper and lower control voltage limits associated with a control voltage V_C and controlling a capacitance associated with the VCO based on the control voltage V_C to tune the frequency of oscillation of the VCO. It is noted, however, that in other embodiments the communication system may include other types of communication devices.

While the embodiments are described with reference to various implementations and exploitations, it will be understood that these embodiments are illustrative and that the scope of the inventive subject matter is not limited to them. Many variations, modifications, additions, and improvements are possible.

Plural instances may be provided for components, operations or structures described herein as a single instance. Finally, boundaries between various components, operations and data stores are somewhat arbitrary, and particular operations are illustrated in the context of specific illustrative configurations. Other allocations of functionality are envisioned and may fall within the scope of the inventive subject matter. In general, structures and functionality presented as separate components in the exemplary configurations may be implemented as a combined structure or component. Similarly, structures and functionality presented as a single component may be implemented as separate components. These and other variations, modifications, additions, and improvements may fall within the scope of the inventive subject matter.